AI Article Synopsis
- The study focuses on a new machine learning method to improve the detection of aluminum and fluoride ions in water, which are harmful to both ecosystems and human health.
- It uses specially designed carbon dots that fluoresce in response to aluminum and change when exposed to fluoride, allowing for precise measurements at very low concentrations.
- The model's effectiveness is confirmed through cluster and regression analyses, proving it to be a promising tool for enhancing environmental monitoring and public health safety.
Article Abstract
The presence of aluminum (Al) and fluoride (F) ions in the environment can be harmful to ecosystems and human health, highlighting the need for accurate and efficient monitoring. In this paper, an innovative approach is presented that leverages the power of machine learning to enhance the accuracy and efficiency of fluorescence-based detection for sequential quantitative analysis of aluminum (Al) and fluoride (F) ions in aqueous solutions. The proposed method involves the synthesis of sulfur-functionalized carbon dots (C-dots) as fluorescence probes, with fluorescence enhancement upon interaction with Al ions, achieving a detection limit of 4.2 nmol/L. Subsequently, in the presence of F ions, fluorescence is quenched, with a detection limit of 47.6 nmol/L. The fingerprints of fluorescence images are extracted using a cross-platform computer vision library in Python, followed by data preprocessing. Subsequently, the fingerprint data is subjected to cluster analysis using the K-means model from machine learning, and the average Silhouette Coefficient indicates excellent model performance. Finally, a regression analysis based on the principal component analysis method is employed to achieve more precise quantitative analysis of aluminum and fluoride ions. The results demonstrate that the developed model excels in terms of accuracy and sensitivity. This groundbreaking model not only showcases exceptional performance but also addresses the urgent need for effective environmental monitoring and risk assessment, making it a valuable tool for safeguarding our ecosystems and public health.
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| http://dx.doi.org/10.1016/j.jes.2024.01.023 | DOI Listing |
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